Effects of isoflurane anesthesia on physiological parameters in murine subcutaneous tumor allografts measured via diffuse reflectance spectroscopy

: Diffuse reflectance spectroscopy (DRS) has been used in murine studies to quantify tumor perfusion and therapeutic response. These studies frequently use inhaled isoflurane anesthesia, which depresses the respiration rate and results in the desaturation of arterial oxygen saturation, potentially affecting tissue physiological parameters. However, there have been no controlled studies quantifying the effect of isoflurane anesthesia on DRS-derived physiological parameters of murine tissue. The goal of this study was to perform DRS on Balb/c mouse (n = 10) tissue under various anesthesia conditions to quantify effects on tissue physiological parameters, including total hemoglobin concentration, tissue oxygen saturation, oxyhemoglobin and reduced scattering coefficient. Two independent variables were manipulated including metabolic gas type (pure oxygen vs. medical air) and isoflurane concentration (1.5 to 4.0%). The 1.5% isoflurane and 1 L/min oxygen condition most closely mimicked a no-anesthesia condition with oxyhemoglobin concentration within 89% ± 19% of control. The time-dependent effects of isoflurane anesthesia were tested, revealing that anesthetic induction with 4.0% isoflurane can affect DRS-derived physiological parameters up to 20 minutes post-induction. Finally, spectroscopy with and without isoflurane anesthesia was compared for colon tumor Balb/c-CT26 allografts (n = 5) as a representative model of subcutaneous murine tumor allografts. Overall, isoflurane anesthesia yielded experimentally-induced depressed oxyhemoglobin,


Introduction
Diffuse reflectance spectroscopy (DRS) is a non-invasive method which can be used to quantify volumetric total hemoglobin concentration (THC), tissue oxygen saturation (StO 2 ), and tissue scattering at or within accessible tissue sites [1][2][3][4][5][6][7][8][9][10]. This technique has been adapted for studies of tumor perfusion and response to therapy, since THC and StO 2 can be used to differentiate therapeutic responders from non-responders over the course of treatment [11][12][13]. DRS is widely used in murine studies in which subcutaneous or orthotopic tumor models are treated with anti-cancer agents or radiation therapy and tumor perfusion is monitored longitudinally over time [14][15][16][17][18]. For example, Turley et al. used a handheld DRS probe to show that Bevacizumab, an anti-VEGF monoclonal antibody, decreased oxyhemoglobin (THC * StO 2 ) in melanoma tumor xenografts over a 7-day study [14]. Spliethoff et al. used DRS to show that cisplatin, a chemotherapy drug, caused an increase in tumor StO 2 in an orthotopic model of mammary tumors over a 7-day study [15]. Finally, Hu et al. used DRS to show that oxygenation kinetics of pharynx squamous cell carcinoma xenografts changed prior to tumor volume changes in response to radiation therapy [16]. These studies indicate that DRS provides clinically relevant, quantitative, and functional information that can be used to monitor tumor response to various types of chemotherapy, radiation therapy, or immunotherapy.
Anesthesia is typically used in murine studies because it reduces the animals' stress, enables easy manipulation of the mice, allows for injections of cancer cells and anti-cancer agents, and allows for accompanying surgical procedures. Anesthetic agents used in mouse studies can be delivered via inhalational (isoflurane or sevoflurane) or injected (pentobarbital or ketamine/xylazine) routes [19]. According to the American Veterinary Medical Association (AVMA), the Institute for Laboratory Animal Research (ILAR), and the Cornell University Institutional Animal Care and Use Committee (IACUC), the most common and recommended anesthesia technique for mice is inhaled isoflurane, a halogenated anesthetic gas supplemented with either 21% (i.e. room air equivalent) or 100% oxygen (O 2 ) [19][20][21]. The minimum alveolar concentration (MAC), which is the anesthesia required to prevent movement in response to surgical stimuli in 50% of subjects, is 1.4% for mice under isoflurane anesthesia [19]. Therefore, the most common practice in DRS studies is placing mice in an induction chamber where anesthesia is quickly induced at 3.0-5.0% isoflurane, and then transferred to a nose cone where anesthesia is maintained at 1.5-3.0% isoflurane, with a constant gas flow rate of 1 L/min [14-17, 19, 22-25]. Isoflurane is a respiratory and myocardial depressant, which causes increased partial pressure of carbon dioxide and bicarbonate levels in arterial blood [26,27]. Thus, even in the presence of O 2 delivery via nose cone, isoflurane results in tissue O 2 desaturation, which may be a confounding variable when studying tissue perfusion of subcutaneous murine models in response to therapy. Additionally, some therapies, such as chemotherapy or immunotherapy, depend on adequate tissue perfusion and O 2 saturation to be effective [28]. DRS can quantify these perfusion metrics and help understand if limitations exist for emerging cancer therapies [29]. However, there have been no studies analyzing the effects of isoflurane anesthesia on DRS-derived physiological parameters of murine tissue.
The present study fills this knowledge gap by monitoring DRS-derived physiological parameters of murine tissue while mice were under various anesthesia conditions. Physiological parameters studied include THC, StO 2 , tissue oxyhemoglobin (HbO 2 ), and reduced scattering coefficient (μ s '). It should be noted that DRS quantifies average StO 2 sampled by light, rather than arterial oxygen saturation (SaO 2 ), venous oxygen saturation (SvO 2 ), or peripheral oxygen saturation (SpO 2 ) [30,31]. StO 2 linearly correlates with the average of SaO 2 and SvO 2 ; thus, StO 2 values are significantly lower than SaO 2 [32]. HbO 2 is the product of THC and StO 2 , and describes the concentration of O 2 -bound hemoglobin in circulation [33,34]. This study was divided into four aims: 1) examine the effects of isoflurane anesthesia on DRS-derived physiological parameters of normal immunocompetent mouse tissue, 2) determine optimal anesthetic conditions for performing DRS while adhering to AVMA and IACUC standards [19][20][21], 3) characterize the time-dependent response of physiological parameters while maintaining mice on 1.5% isoflurane after induction with either 1.5% or 4.0% isoflurane, and 4) validate findings in a subcutaneous murine allograft model of colon carcinoma. An allograft model of colon carcinoma was chosen because they are well-established models in literature but are understudied regarding DRS. For the first aim, physiological parameters were quantified after manipulating two variables including metabolic gas type (O 2 vs. medical air) and isoflurane concentration (1.5% to 4.0%). For the second aim, optimal anesthetic conditions were determined based on least significant differences between control (no-anesthesia) and experimental groups. For the third aim, mice were anesthetically induced with either 4.0% isoflurane for one minute or 1.5% isoflurane for four minutes. Following induction, mice were transferred to a nose cone and maintained on 1.5% isoflurane for 15 minutes to determine how initial induction conditions affect physiological properties over time. Physiological parameters were monitored via DRS every minute. Finally, for the fourth aim, an allograft model of murine colon carcinoma was used to demonstrate expected changes in DRS-derived tumor physiological parameters during isoflurane anesthesia.
The central hypothesis was that DRS can accurately monitor physiological changes associated with isoflurane anesthesia. Specially, isoflurane anesthesia was expected to yield experimentally-induced low StO 2 and HbO 2 , but insignificant changes in THC and μ s ', for both normal and subcutaneous tumor sites. Optimal anesthesia conditions were expected to occur at the lowest tested isoflurane concentration (1.5%) with 100% O 2 . Furthermore, StO 2 and HbO 2 were expected to change over time in response to anesthesia. This work aims to guide investigators in eliminating, limiting, or managing anesthesia-induced physiological changes in DRS studies in mouse models.

Murine models
The study was approved by the University of Arkansas Institutional Animal Care and Use Committee (IACUC #18060). Fifteen female Balb/c mice (strain: 000651, The Jackson Laboratory, ME, USA) aged nine weeks were purchased. Balb/c mice were housed in groups of three in five cages at 23°C ± 1°C and 50% ± 10% humidity on a 12:12 hour light-dark cycle. Food (8640, Teklad) and water was provided ad libitum. All 15 mice acclimated for seven days, including daily handling (2 minutes) for adaptation to future measurements, after arrival prior to the start of the study. After one week of acclimation, left flanks of the 10-week old Balb/c mice were shaved and Nair depilatory was applied for one minute to locally remove fur.

Cell line for allograft model of colon carcinoma
Five of the 15 Balb/c mice were randomly selected for tumor allotransplantation. CT26 (ATCC, CRL-2638), a colon carcinoma cell line derived from the Balb/c mouse strain, was maintained in Roswell Park Memorial Institute (RPMI)-1640 medium (ATCC,  supplemented with 10% fetal bovine serum (ATCC, 30-2020), 1% antibiotic antimycotic solution (Sigma-Aldrich, A5955-100ML), and 0.2% amphotericin B/gentamicin (Thermo Fisher Scientific, R015010) at 37°C and 5% CO 2 . CT26 cells were brought to the third passage (P3). Then, 1x10 5 CT26 cells in sterile saline were injected subcutaneously into the left flank. Tumor allografts grew until they reached a volume of 100 mm 3 , measured via , which took 14.4 ± 2.2 days, upon which tumor underwent DRS measurements. Then, tumor allografts continued to grow until they reached 500 mm 3 , approximately 18.1 ± 1.2 days following implantation, upon which additional DRS measurements were taken to compare physiological parameters at different tumor sizes in response to isoflurane anesthesia. For controls, adjacent healthy flank tissue was measured.

Diffuse reflectance spectroscopy instrumentation
The custom, handheld DRS probe (FiberTech Optica, Kitchener, ON, Canada) was used in direct contact with tissue to perform all spectroscopy measurements. The brass probe tip is cylindrical with a diameter of 6.35 mm. The probe includes a 400 μm-core source fiber (FiberTech Optica, SUV400/440PI, 0.22 ± 0.02 NA) which delivers broadband light (450-900 nm) from a 20W tungsten-halogen lamp (Ocean Optics, HL-2000 HP) into tissue, and an adjacent 400-μm core detector fiber (FiberTech Optica, SUV400/440PI, 0.22 ± 0.02 NA) which transfers diffusely reflected light to a spectrometer (Ocean Optics, FLAME-S) with an optical resolution of 2.1 nm. The center-to-center source-detector separation (SDS) between these two optical fibers was 3.00 mm. All DRS measurements were performed in a dark environment.
The four physiological parameters were quantified by inputting raw DRS spectra into an experimental lookup-table (LUT)-based post-processing software with a priori values for oxygenated and deoxygenated hemoglobin extinction coefficients [8, 35,36]. The software performed an iterative model fit, based on a standard damped least-squares nonlinear fitting method, on raw DRS data to quantify THC, StO 2 , HbO 2 , and μ s ' [8]. Additionally, the chisquared (Χ 2 ) value indicated goodness-of-fit between the model fit and raw DRS data; for this study, if Χ 2 values exceeded 1.0, data was rejected and re-acquired as this was likely due to user-induced movement artifacts during data collection (i.e. discarding data taken with small air gaps between probe and skin). Finally, the software is based on a fitting range (i.e. boundary conditions) for all four physiological parameters, as shown in Table 1. Lower and upper bounds were set to encompass a wide range of potential physiological parameters in murine skin and tumor tissue [37,38]. The wavelength range used to fit the data was between 450 to 900 nm.

Controlling for confounding variables in mouse diffuse reflectance spectroscopy
Positioning of the mice during DRS measurements could potentially affect results by changing venous blood distribution. Therefore, for DRS measurements of mice under isoflurane anesthesia, mice were placed in the prone position. For DRS measurements of non-anesthetized mice, mice sat in the operator's hand. Thus, the tumor and adjacent healthy skin were identically oriented during measurements in both anesthesia and non-anesthesia cases. Next, the method of restraining non-anesthetized animals during measurements could affect results by increasing stress leading to altered hemodynamic and tissue blood volume levels [39,40]. Mice were restrained by holding the base of the tail between index and middle fingers and allowing the mouse to rest in the palm, or, for the anesthesia conditions, in the prone position with a nose cone delivering isoflurane and metabolic gas. Stress was accounted for in two ways. First, all mice were handled daily for 2 minutes during the 7-day acclimation period to allow the mouse to adapt to DRS measurement procedures and provide reproducible results [40]. Additionally, mouse respiration rate was monitored during experiments. During DRS measurements of anesthetized animals, respiration rate was monitored visually by an operator not performing measurements. Safe respiration rate under anesthesia is 55-70 breaths per minute [41]. During DRS measurements of non-anesthetized animals, breath rate was not to exceed 150 breaths per minute (BPM) or a 10% increase from baseline prior to handling [41]. If BPM did not fall within these stress-related criteria, DRS measurements were not taken.
Finally, previous research has shown that absorption due to THC and StO 2 decreases with both increasing probe-tissue pressure and time since the probe may physically compress blood out of the tissue site and impede the sampled tissue site from receiving replacement oxygenated blood [42]. Although probe-pressure effects were not directly measured in this study, probe-pressure effects have been shown to be nearly negligible (< 5% error) within a range of probe-skin pressures between 9 to 152 mN/mm 2 (1.3 to 22.0 PSI) using a similar 6.35 mm-diameter DRS probe in short (< 2 s) contact durations. Normal probe-skin pressure tends to be less than 9 mN/mm 2 , and, for our setup, a contact time less than 1 s, justifying the non-use of an integrated pressure sensor [42].

Effect of isoflurane concentration on physiological tissue parameters
The aim of this experiment was to examine the effect of inhaled isoflurane anesthesia physiological parameters of murine tissue, measured by DRS, and determine optimal anesthetic conditions for DRS.
The normal, exposed left flank of Balb/c mice (n = 10) underwent DRS with varying anesthesia conditions. The control group received no anesthesia. Subsequent groups received isoflurane anesthesia (Henry Schein Animal Health, 1169567762) using a tabletop laboratory animal anesthesia system (VWR, 89012-492). Metabolic gas was varied between pure O 2 (100% O 2 , Airgas, OX USP200) and medical air (21% O 2 , Airgas, AI USP200), with a constant flow rate of 1 L/min. Isoflurane concentration was varied between 1.5%, 2.0%, 3.0%, and 4.0%. Mice were induced and maintained on the same isoflurane concentration. Concentrations below 1.5% were not tested because such concentrations would be below the MAC value (1.4%) for isoflurane in mice [19]. Isoflurane concentrations above 4.0% were not tested since higher values are usually only used for isoflurane-induced euthanasia according to AVMA [20]. Furthermore, investigators generally do not exceed 4.0% isoflurane during anesthetic induction [14-17, 19, 22-25].
Mice were placed in a 2L induction chamber with an input connected to the isoflurane-gas mix and output connected to a disposable charcoal filter (VWR, 89012-608) housed in an externally ventilating chemical fume hood. Mice were anesthetically induced until they had no pedal reflex (firm toe pinch). Mice were then transferred to a second independent anesthesia circuit consisting of a 9 mm-diameter nose cone with an input connected to the isoflurane-gas mix and output connected to a disposable charcoal filter. To maintain body temperature, mice were placed on a water-based warming pad (Stryker, #TP12E) controlled by a warming pump (Stryker, #TP700) set to 42°C (107°F), as recommended by the Cornell University IACUC [21].

Physiolo
A second co underwent DR with (1.5% iso volumes of 1 placed in the reflex and tra integration tim experimental   Fig. 4(b)), t rage values fo pidly, even at O 2 decreased to hin both O 2 and flurane, StO 2 st (Fig. 4(c)), de and StO 2 , there ane (p = 0.04), to DRS-derive etween using 1 < 0.01) grou n (1.5%) above Fig. 4(d) (Fig. 5(b) Finally, μ with 1.5% iso period and D consciousness were gently r middle finger increased with the five-minu minutes of rec From thes with both 1.5% begins, that recover to th parameters fu Colon carcino were compar μ s ' (Fig. 4(d) without isoflurane anesthesia to quantify physiological parameters (Fig. 6). All mice were induced with 1.5% isoflurane for four minutes to avoid the effects of 4.0% isoflurane seen in Fig. 4.

Physiolo
For adjacent tissue locations (no tumor), there was significant reduction in physiological parameters for the anesthesia condition compared to the no anesthesia condition for THC (p < 0.01), StO 2 (p = 0.04), and HbO 2 (p = 0.02). However, overall trends within the anesthesia and no anesthesia groups were similar, with insignificant reductions in physiological parameters when using 1.5% isoflurane and 1 L/min O 2 . Additionally, as tumor size increased, StO 2 and HbO 2 decreased while THC increased and μ s ' remained constant. Further comparisons across and within groups were visually expressed in Fig. 6.

Discussion
Isoflurane anesthesia is a known respiratory and myocardial depressant, causing increased serum carbon dioxide and bicarbonate levels, and decreased arterial pressure. Despite this, isoflurane is commonly applied as an anesthetic agent in studies investigating volumetric perfusion of murine tissue, which is the aim of many DRS-based studies. To better understand the effects of isoflurane anesthesia on DRS-derived physiological parameters, the present study monitored murine THC, StO 2 , HbO 2 , and μ s ' using DRS under various anesthesia conditions. Understanding the effects of isoflurane anesthesia on these tissue physiological parameters will help guide investigators in DRS experimental design.
In this study, increasing isoflurane concentration significantly decreased THC, StO 2 , and HbO 2 while having no effect on µ s ' (Figs. 4-6). Of all four DRS-derived physiological parameters, StO 2 was most influenced by changes in isoflurane concentration. Furthermore, using 100% O 2 , rather than 21% O 2 , resulted in closer approximation to no-anesthesia controls (Fig. 4), a trend echoed by Gerling et al. who showed that supplying 100% O 2 led to increased StO 2 [43]. Because of this, 100% O 2 was used throughout the remainder of the study.
In Fig. 4(b), StO 2 did not decrease (50% to 48%, p = 0.32) when comparing the noanesthesia control to the 1.5% isoflurane condition. However, StO 2 drastically decreased from 48% to 6% when increasing isoflurane from 1.5% to 4.0% in normal tissue. StO 2 values of ~6% have been observed in similar spectroscopy studies of mice tissue during anesthesia [15]. StO 2 linearly correlates with the average of SaO 2 and SvO 2 ; thus, StO 2 values are significantly lower than SaO 2 [32], which can be measured via pulse oximetry [44]. Decreased StO 2 is primarily caused by isoflurane-induced decreased mean arterial blood pressure (MAP) [45]. Szczesny et al. measured MAP of mice under increasing isoflurane concentrations, and showed that MAP decreased from 80 mmHg to below 40 mmHg as isoflurane concentration was increased from 1.0% to 4.0% [46]. Constantinides et al. echoed this trend, showing that MAP decreased from 85 mmHg to 73 mmHg when increasing isoflurane concentration from 1.0% to 2.0% with 100% O 2 . Additionally, this research showed that MAP decreased from 92 mmHg to 84 mmHg when decreasing O 2 from 100% to 21% with 1.5% isoflurane [47].
To our knowledge, no other studies report StO 2 (as low as 6% in Fig. 4(b)) at high (4.0%) concentrations of isoflurane, since many studies state they DRS acquisition during isoflurane maintenance of 1.5%. However, this statement paints an incomplete picture. This report is important because the most common anesthetic practice in DRS studies is placing mice in an induction chamber where anesthesia is induced at ~4.0% isoflurane [19]. This isoflurane concentration can have long-lasting effects on blood physiology, even when mice are transferred to a nose cone where isoflurane is maintained at 1.5% (Fig. 5). Therefore, we show that isoflurane induction, not just maintenance, highly affects DRS-derived StO 2 (Fig.  5). We recommend 1.5% isoflurane with 100% O 2 for both induction and maintenance, despite increased time to loss of pedal reflex.
Of note are conflicting results from a study by Farzam et al. In this study, mice were anesthetized and maintained on 3.5% and 2.0% isoflurane, respectively, and StO 2 values were ~75% in orthotopic renal cell carcinoma tumors [48], a stark increase from our StO 2 of 22% at 2.0% isoflurane (Fig. 4(b)). However, this study analyzed an orthotopic, rather than subcutaneous, tumor model of a different cell line. In a more comparable study, Rajaram et al. reported StO 2 values near 30% under similar isoflurane conditions (1.5%) and wavelength ranges (350 to 850 nm) of murine skin at a comparable SDS (2.5 mm) [49]. The wavelength range used to fit data and SDS are paramount when comparing between studies.
Unlike hemodynamic physiological parameters, the µ s ' was unaffected by changes in isoflurane concentration and O 2 levels. Tissue scattering is primarily caused by local density of lipid membranes from cellular tissues, mitochondria, lysosomes, and collagenous tissue like the skin [50], which was the primary tissue type interrogated in this experiment. These scattering structures are unaffected by isoflurane conditions, resulting in stable µ s '.
Based on these results, isoflurane anesthesia should be carefully considered when performing DRS studies to quantify THC, StO 2 , and HbO 2 ; however, some invasive and minimally invasive studies cannot eliminate the anesthesia use. is recommended in these cases. Using a minimum of 1.5% isoflurane for induction over a four-minute period also drastically decreased StO 2 and HbO 2 , although changes were slower to occur compared to 4.0% isoflurane induction (Fig. 5). If anesthesia is needed when measuring in vivo physiological parameters via DRS, it may be more representative to slowly induce anesthesia with 1.5% isoflurane rather than rapidly inducing anesthesia with 4.0% isoflurane and lowering concentration for anesthesia maintenance.
Finally, THC, StO 2 , HbO 2 , and μ s ' of Balb/c-CT26 colon tumor were measured via DRS. Figure 6a indicates that increased tumor volume correlates to increased THC. Across Figs. 4-6, we report THC of 2.8 to 4.0 mg/mL in normal tissue and 4.0 to 4.8 mg/mL in subcutaneous CT26 tumor allografts under 1.5% isoflurane anesthesia, comparable to a study by Spliethoff et al [15] in similar conditions. Increased tumor THC is due to increased tumor microvasculature coupled with increased ratio of deoxyhemoglobin to oxyhemoglobin. This trend of increased tumor THC is well known [52,53]. Figure 6b shows that StO 2 of tumors with volumes of 500 mm 3 was ~14%, both with and without 1.5% isoflurane. This low StO 2 value is similar to a study by Spliethoff et al., which reported slightly lower StO 2 values of 2-6% in larger mammary xenograft tumors (up to 800 mm 3 ) using 1.5% isoflurane anesthesia [15]. Rich et al. reported similar StO 2 values of 5-15% in head and neck cancer xenograft tumors, measured using photoacoustic imaging [54]. Finally, Rajaram et al. reported DRSderived StO 2 around 20% for mammary xenografts at 1.5% isoflurane anesthesia [49]. The Rajaram study also reported a ~1.5x decrease in StO 2 of 100 mm 3 mammary tumor xenografts compared to normal tissue, whereas this present study reports a ~1.6x decrease (Fig. 6(b)) in StO 2 of 100 mm 3 colon tumor allografts compared to normal tissue. The comparable StO 2 values in these studies lend support to our results. HbO 2 in Fig. 6(c) demonstrates similar trends as StO 2 . In Fig. 6(d), µ s ' was unaffected by tumor size and isoflurane, similar to Figs. 4 and 5.
Additionally, in tumors, there were insignificant decreases in THC, StO 2 , and HbO 2 when using 1.5% isoflurane compared to a no-anesthesia control, suggesting it may be appropriate to monitor percent changes in physiological parameters over time. In longitudinal treatment studies, accompanying non-endpoint procedures such as chemotherapy, radiation therapy, immunotherapy, or other treatment or observation procedures requiring anesthesia should ideally be performed after DRS measurements have concluded.
One limitation of this study is the focus on non-invasive DRS of readily accessible murine tissue, such as skin and subcutaneous tumor allografts, which only requires contact between the probe and skin directly overlying the tumor. Additionally, DRS was the only technique used to quantify THC, StO 2 , HbO 2 , and μ s ' and cannot provide insights into tumor vascular heterogeneity [8, [55][56][57]. Other optical techniques exist to quantify these parameters including diffuse optical imaging (DOI) [55], hyperspectral imaging [58], and near infrared spectroscopy (NIRS), which extends the wavelength range of DRS into the near infrared to quantify additional endogenous chromophores such as fat and water [15, [59][60][61]. For example, DOI combined with magnetic resonance imaging can differentiate tumors with low and high vascular heterogeneity, and hyperspectral imaging can quantify vascular O 2 supply and blood flow in rodent models. These spectral and imaging techniques would benefit from an in-depth analysis at how anesthetic drugs affect results. Next, DRS-derived physiological parameters were only quantified in response to isoflurane anesthesia. Despite being the most common type of anesthetic used in DRS-based mouse studies, other anesthesia drugs exist including sevoflurane, Pentobarbital, and ketamine/xylazine [19]. Finally, further tests with additional cell lines for murine subcutaneous allografts or xenografts will generalize results. An allograft model of colon carcinoma (Balb/c-CT26) was chosen because they are wellestablished models in literature but are understudied regarding DRS. Results compare well with other allograft/xenograft tumors in terms of physiological parameters (THC, StO 2 , HbO 2 , and μ s ').
The findings presented here suggest that DRS is a valid tool to dynamically monitor changes in physiological parameters. These findings indicate that DRS has the potential to help investigators understand if limitations exist for certain cancer therapies that directly depend on tumor O 2 consumption and help guide investigators in managing anesthesiainduced physiological changes in DRS studies of murine subcutaneous tumor allografts. Future studies analyzing DRS-derived physiological parameters in response to these drugs will increase the generalization of our findings.

Conclusion
Diffuse reflectance spectroscopy can be effectively used to monitor dynamic fluctuations in tissue physiological parameters, such as total hemoglobin concentration, tissue oxygen saturation, oxyhemoglobin, and tissue scattering, and is an attractive tool for monitoring tumor response to therapy. Additionally, diffuse reflectance spectroscopy has the potential to help investigators understand if limitations exist for certain cancer therapies, such as chemotherapy or PDT, that directly depend on oxygen consumption and well-perfused tumors. Investigators using this tool should understand the dynamic effects of isoflurane concentration on resulting physiologic values. We show that isoflurane induction, not just maintenance, highly affect hemodynamic parameters. Alternative methods to diffuse reflectance spectroscopy, such as pulse oximetry, should be considered when monitoring arterial, rather than tissue, oxygen saturation, during anesthesia.

Funding
National Institutes of Health (1R15CA202662-01); National Science Foundation Graduate Research Fellowship Program (G.G., DGE-1450079); the Arkansas Biosciences Institute; the University of Arkansas Doctoral Academy Fellowship.